Difference between revisions of "Mock AIME II 2012 Problems/Problem 13"

Latest revision as of 19:32, 27 December 2012

Problem

Regular octahedron $ABCDEF$ (such that points $B$ , $C$ , $D$ , and $E$ are coplanar and form the vertices of a square) is divided along plane $\mathcal{P}$ , parallel to line $BC$ , into two polyhedra of equal volume. The cosine of the acute angle plane $\mathcal{P}$ makes with plane $BCDE$ is $\frac{1}{3}$ . Given that $AB=30$ , find the area of the cross section made by plane $\mathcal{P}$ with octahedron $ABCDEF$ .

Solution

Let $O$ be the center of the octahedron. The plane must pass through $O$ in order to bisect the area of the octahedron. We see that the cross-section will be a hexagon as it passes through six of the eight faces. By symmetry, the area of this hexagon is twice that of the trapezoid contained within square pyramid $ABCDE$ .

We proceed by finding the height of the square pyramid, which is $AO$ . The altitude from $A$ to $BC$ of $\Delta ABC$ is $15\sqrt{3}$ . The distance from $O$ to the midpoint of $BC$ is half the side length of the square $BCDE$ , so its $15$ . The altitude of $\Delta ABC$ , the segment joining $O$ and the midpoint of $BC$ , and $AO$ make a right triangle. Then by the Pythagorean Theorem, $AO^2+15^2=(15\sqrt3)^2$ so $AO = 15\sqrt2$ . Now consider $\angle A$ of this right triangle. We have $\sin A = \frac{15}{15\sqrt3} = \frac{1}{\sqrt3}$ . This will be important later.

Back to the trapezoid. One of its bases is on $BCDE$ and the other base must be on $ABC$ or $ADE$ (it cannot be on the other two faces as it is parallel to $BC$ ). WLoG let the base be on $\Delta ABC$ . Let $M$ be the midpoint of this base and consider $\Delta OAM$ . We have that $\angle AOM$ is the complement of the angle between the plane $\mathcal{P}$ and the square $BCDE$ . Then $\sin \angle AOM = \frac{1}{3}$ . Now consider $\angle OAM$ . This is the same angle as the $\angle A$ we had before. Then $\sin \angle OAM = \frac{1}{\sqrt 3}$ .

Now by the Law of Sines $\frac{AM}{\sin \angle AOM} = \frac{OM}{\sin \angle OAM}$ so $AM = \frac{OM}{\sqrt3}$ . By the Law of Cosines, $AM^2 = (15\sqrt2)^2+OM^2 -2(OM)(15\sqrt2)(\frac{1}{3})$ . This solves to $OM = 15$ and $AM = 5\sqrt3$ . We reject the solution $OM = 45$ as it is too large; $AO=15\sqrt2$ must be largest side in $\Delta AOM$ as $\angle M$ is the largest angle. We know this as the other angles have sines less that $\sin 45 = \frac{1}{\sqrt 2}$ and so have values less than $45$ .

Now on $\Delta ABC$ we have that the second base is parallel to $BC$ . Let $b$ be the length of the second base. Then by the two similar triangles, $\frac{b}{AM} = \frac{BC}{15\sqrt{3}}$ where we have compared the side length of the triangles to their heights. As $BC = 30$ is a given, this solves to $b = 10$ .

Then the area of the trapezoid is $\frac{1}{2}(OM)(30+ b) = \frac{1}{2}(15)(30+10) = 300$ . The area of the whole hexagon is twice this, so the final answer is $\boxed{600}$

@@ Line 10: / Line 10: @@
 Back to the trapezoid. One of its bases is on <math>BCDE</math> and the other base must be on <math>ABC</math> or <math>ADE</math> (it cannot be on the other two faces as it is parallel to <math>BC</math>). WLoG let the base be on <math>\Delta ABC</math>. Let <math>M</math> be the midpoint of this base and consider <math>\Delta OAM</math>. We have that <math>\angle AOM</math> is the complement of the angle between the plane <math> \mathcal{P} </math> and the square <math>BCDE</math>. Then <math>\sin \angle AOM = \frac{1}{3}</math>. Now consider <math>\angle OAM</math>. This is the same angle as the <math>\angle A</math> we had before. Then <math>\sin \angle OAM = \frac{1}{\sqrt 3}</math>.
-Now by the Law of Sines <math>\frac{AM}{\sin \angle AOM} = \frac{OM}{\sin \angle OAM}</math> so <math>AM = \frac{OM}{\sqrt3}</math>. By the Law of Cosines, <math>AM^2 = (15\sqrt2)^2+OM^2 -2(OM)(15\sqrt2)(\frac{1}{3})</math>. This solves to <math>OM = 15</math> and <math>AM = 5\sqrt3</math>. We reject the solution <math>OM = 45</math> as it is too large; <math>AO=15\sqrt2</math> must be largest side in <math>\Delta AOM</math> as <math>\angle M</math> is the largest angle. We know this as the other angles have sines less that <math>\sin 45 = \frac{1}{\sqrt 2}</math> and so have values less than 45.
+Now by the Law of Sines <math>\frac{AM}{\sin \angle AOM} = \frac{OM}{\sin \angle OAM}</math> so <math>AM = \frac{OM}{\sqrt3}</math>. By the Law of Cosines, <math>AM^2 = (15\sqrt2)^2+OM^2 -2(OM)(15\sqrt2)(\frac{1}{3})</math>. This solves to <math>OM = 15</math> and <math>AM = 5\sqrt3</math>. We reject the solution <math>OM = 45</math> as it is too large; <math>AO=15\sqrt2</math> must be largest side in <math>\Delta AOM</math> as <math>\angle M</math> is the largest angle. We know this as the other angles have sines less that <math>\sin 45 = \frac{1}{\sqrt 2}</math> and so have values less than <math>45</math>.
 Now on <math>\Delta ABC</math> we have that the second base is parallel to <math>BC</math>. Let <math>b</math> be the length of the second base. Then by the two similar triangles, <math>\frac{b}{AM} = \frac{BC}{15\sqrt{3}}</math> where we have compared the side length of the triangles to their heights. As <math>BC = 30</math> is a given, this solves to <math>b = 10</math>.
 Then the area of the trapezoid is <math>\frac{1}{2}(OM)(30+ b) = \frac{1}{2}(15)(30+10) = 300</math>. The area of the whole hexagon is twice this, so the final answer is <math>\boxed{600}</math>

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Difference between revisions of "Mock AIME II 2012 Problems/Problem 13"

Latest revision as of 19:32, 27 December 2012

Problem

Solution